Optimization of Polymer Processing: A Review (Part I- Extrusion)

Article

Optimization of Polymer Processing:

A Review (Part I- Extrusion)

António Gaspar-Cunha ^1*, José A. Covas ² and Janusz Sikora ³

1 Institute of Polymers and Composites, University of Minho, [email protected], [email protected]

2 Institute of Polymers and Composites, University of Minho, [email protected]

3 Department of Technology and Polymer Processing, Faculty of Mechanical Engineering, Lublin University of Technology, Nadbystrzycka 36, 20-618 Lublin, Poland, [email protected]

* Correspondence: [email protected]; Dept. of Polymer Engineering, Campus de Azurém, University of Minho, Guimarães, Portugal

Abstract: Given the global economic and societal importance of the polymer industry, the continu- ous search for improvements in the various processing techniques is of practical primordial im- portance. This review evaluates the application of optimization methodologies to the main polymer processing operations. The most important characteristics related with the usage of optimization techniques, such as the nature of the objective function, the type of optimization algorithm, the modelling approach used to evaluate the solutions, and the parameters to optimize, are discussed.

The aim is to identify the most important features of an optimization system for polymer processing problems, and define the best procedure for each particular practical situation. For this purpose, a state-of-the-art of the optimization methodologies usually employed is first presented, followed by an extensive review of the literature dealing with the major processing techniques, the discussion being completed by considering both the characteristics identified and the available optimization methodologies. This first part of the review focus on extrusion, namely extruders, extrusion dies and calibrators. It is concluded that there is a set of methodologies that can be confidently applied in polymer processing, with a very good performance and without the need of demanding compu- tation requirements.

Keywords: polymer processing, single screw, twin screw, injection molding, blow molding, ther- moforming, optimization, artificial intelligence

1. Introduction

Polymer processing is an important industrial activity that converts raw materials, such as polymers, polymer compounds, polymer blends, composites and nanocompo- sites, into useful products mostly for applications in packaging, building and construc- tion, mobility, electrical and electronics, medical, agriculture, household, leisure and sports. For example, in 2019 more than 55000 European companies (plastics raw materials producers, plastics converters, recyclers and machinery manufacturers in the EU28 Mem- ber States) employed over 1.5 million people, and converted 50.7 Mt of plastics [1]. A pro- gressively more sustainable and better performing range of polymer systems, together with increasingly more efficient and intelligent extrusion, injection molding, blow mold- ing and thermoforming – the most important processing techniques for thermoplastics – are paramount to create or improve products with more advanced performances and functionalities.

Thermoplastics processing typically involves three functional steps: plasticization of a solid polymer (usually supplied in pellet form), flow and shaping of the melt, and cool- ing. Thus, an understanding of polymer processing requires a good knowledge of heat transfer, melt rheology, fluid mechanics, morphology development, among others. In the case of reactive extrusion, plasticization is combined with chemical reactions (polymer synthesis and/or modification) into a single process. In their seminal book on polymer

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processing, Tadmor and Gogos [2] proposed a structural breakdown of polymer pro- cessing into elementary steps, based on the principles of transport phenomena, fluid me- chanics, heat and mass transfer, polymer melt rheology, solid mechanics, physics and chemistry of polymers and mixing, which provide the basic tools for quantitatively ana- lyzing polymer processing.

It is well recognized that the geometry of the processing equipment, the operating conditions selected, and the properties of the polymer system being processed determine the resulting morphology of the part, and hence its practical performance. This has fos- tered extensive experimental investigation with the aim of obtaining a good understand- ing of the physical, thermal, rheological and chemical processes developing during poly- mer processing. Historically, the screw extraction experiments carried out by Maddock [3] were particularly relevant to shed light on plasticating extrusion. Once physical mod- els of the underlying phenomena were available, they were translated into mathematical descriptions, either analytical or numerical, depending on the assumptions and simplifi- cations made. Currently, modelling of polymer processing is well developed [2, 4-6], sim- ulation software devoted to various processing techniques being commercially available.

These programs solve the governing equations that describe the phenomena developing along the various individual process stages, coupled to the relevant boundary conditions (operating conditions and equipment geometry) and constitutive equations for the poly- mer properties. The resulting predictions provide a description of how the process will perform under the conditions defined, which is obviously very useful to both processors and equipment/tool manufacturers. In some cases, the morphology of the part (macromo- lecular/fibre orientation, crystallization rate, size of the spherulites, etc.) can be predicted from the knowledge of the thermomechanical process parameters, but the link to the end- use engineering properties entails multi-scale modelling [7], which is still very costly com- putationally.

The direct use of these simulations for practical process troubleshooting, setting the operating conditions, defining a screw profile, designing an extrusion die, an injection mold, or a plastic bottle, would require to tackle the inverse problem, i.e., to solve the set of governing equations of the process in order to the geometrical and operational varia- bles, while prescribing the required performance as boundary condition(s). This is com- plex and usually mathematically ill-posed, as there is no unique relationship between cause and effect. Thus, in practice, four alternative methodologies can be adopted:

1. Use the simulation tools on a trial and error basis. This is obviously expensive and inefficient, and relies on the capability of the user to input progressively more appro- priate boundary conditions;

2. Develop specific design approaches, i.e., using the modelling equations in a prear- ranged sequence. Examples are methods to design extruder screws [8] or extrusion dies [9];

3. Adopt an optimization procedure, whereby the process modelling package is used judiciously by an optimization algorithm, in order to define a “best” solution, or a Pareto optimal solution (see below). Practical polymer processing problems gener- ally involve multi-, often conflicting, criteria (for example maximize output, while minimizing viscous dissipation and mechanical energy consumption in plasticating single screw extrusion), hence this approach is usually labelled as multi-objective op- timization.

4. Perform data-driven optimization, which consists in the use of Artificial Intelligence (AI) techniques to explore the search space based on experimental or computational data [10, 11].

Some of these methodologies were already presented in several reviews analyzing the application of optimization techniques in polymer processing. Kasat et al. [12] dis- cussed the application of Genetic Algorithms (GAs) in polymer science and engineering, stressing the existence of multiple objectives and constraints that must be dealt with sim- ultaneously. Particularly in the area of chemical reactions during polymerization, obtain- ing a polymer with a desired molecular weight requires satisfying simultaneously various

objectives, such as minimizing the reaction time as it implies lower cost, and minimizing the concentration of side products as they decrease the product properties. Oduguwa et al. [13] extended the idea applying Evolutionary Algorithms (EA) to the manufacturing industry, which includes polymer processing. The main justification given for the use of this type of algorithms comes from the fact that the traditional methods frequently em- ployed to solve complex real world problems tend to miss a more efficient exploration of the search space, becoming trapped in sub-optimal regions, while simultaneously they are often computationally expensive. Methodologies based on the use of a population of points (solutions), such as EAs, can overcome this situation, as these points can evolve simultaneously towards the Pareto optimal front, and thus access the global optimal so- lutions. Oduguwa et al. [13] also refer the difficulties that optimization approaches face in being accepted in industry. Recently, Nastaj and Wilczyński [14] addressed the optimiza- tion and scale-up of single and twin screw extrusion. However, they focused on method- ologies developed by specific authors, and the optimization concepts discussed were somewhat limited. Thus, in general, previous reviews on the optimization of polymer pro- cessing excluded several important technological or optimization aspects, are very limited in terms of the analysis performed, and even ignore several important published contri- butions.

After introducing some important concepts of multiobjective optimization, the pre- sent review covers the application of optimization methods to solve real problems in pol- ymer processing, encompassing extrusion, injection molding, blow molding and ther- moforming. Due to the extension of the analysis, the work is divided into two parts. The present part 1 focus on extrusion, namely single and twin screw extruders, extrusion dies and calibrators. The most important contributions to the field are identified and future trends are discussed.

2. Need for Optimization in Polymer Processing

The practical need for optimization, namely in what concerns the process, the design variables, the modelling requirements and the objectives to be attained, will be illustrated with an example dealing with Injection Stretch Blow-Molding, a technique widely used for the manufacture of bottles for plain and carbonated drinks (and dealt with in greater detail in Part 2). Figure 1 illustrates the main production steps (A to E, following the open arrows). An injection unit (A) fills the cavity of an injection mold (B) to produce a pre- form. This is then transferred to a blow-mold (C) where it is stretched and blown (D) against the contours of the mold cavity. Once the container is sufficiently cold, the mold opens (E), the part is removed and a new production cycle is initiated. Modelling this process in order to predict the performance of the part for a given set of input conditions (bottle design, operating conditions, equipment geometry, material properties) typically entails the numerical modelling of each of its individual steps, followed by coupling them through appropriate boundary conditions. Depending on the physical process models considered and consequent ability of the numerical routines, the thickness profile of the product, its morphology, and the mechanical performance could be predicted.

Such a sophisticated tool would be used quite inefficiently if conventional means were adopted. For example, if the aim is to produce a bottle with a minimum weight and a maximum thickness uniformity, the computer model will be used on a trial-end-error basis, with the operator progressively fine tuning the operating conditions and/or bottle design until attaining a satisfactory result. A much more efficient strategy would be to consider again the modelling sequence and solve the inverse problem, whereby the bottle characteristics are imposed as boundary conditions and the equations are solved in order to the operating conditions. This would imply approaching the process backwards, from F to A, as indicated by the curved black arrows in Fig.1. However, this is mathematically ill-posed, as there are no unique relationships between cause and effect.

Alternatively, an optimization problem can be defined, consisting of two objectives (minimize bottle weight and maximize its thickness uniformity) and a restriction (the min- imum thickness must be higher than a pre-defined value). The decision variable is the 3D

thickness distribution of the part that results from all prior process steps, which consti- tutes a huge decision variables space. The optimization can either proceed following steps (i) to (v) in Fig.1, or the system can be considered as a whole and all steps can be optimized simultaneously.

Figure 1. Optimization of Injection Stretch Blow-Molding. (A) to (E) illustrate the process steps. Open ar- rows follow the process sequence; black curved arrows follow the optimization sequence.

Fig. 2 shows results obtained for the optimization of steps (i) and (ii). In step (i) the aim is to define the thickness profile of the bottle that minimizes its weight, the maximum strain under a given load and the thickness uniformity in terms of a parameter RMSE.

Using EAs, an initial population of solutions is generated randomly, evolving until the 100^th generation. From the analysis of the Pareto front, solution S3-i was selected. The fol- lowing optimization problem concerns the blowing phase (here considered to take place after stretching the pre-form), i.e., the optimization of the thickness profile of the preform that produces the optimal bottle thickness profile found in the first step. For that purpose, the mean (f¹) and the maximum (f²) errors between the optimal thickness distribution and the thickness distribution of the parison must be minimized. More details on this optimi- zation can be found elsewhere [15, 16].

Figure 2. Typical results for the blow-molding optimization example: solution S3-i is selected for step (ii), from which a new Pareto set is obtained.

3. Multi-Objective Optimization

The aim of optimization is to find the best set of decision variables, i.e., a solution, that optimizes an objective function on a given search space, often in the presence of equal- ity and/or inequality constraints, with the main purpose of approaching that solution to a global optimum [17]. Without loss of generality, in the case of a maximization problem, the mathematical formulation is the following:

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where f is the objective function of the N parameters xi, gj are the J (J≥0) inequality con- straints, and h^k are the K (K≥0) equality constraints.

In the absence of a systematic procedure, a traditional way of finding the best possi- ble solution consists in performing a statistical and/or regression analysis based on exper- imental or computational results. From a set of data, it is possible to deduce a mathemat- ical model relating the objective function (f) with the decision variables (xi). From this model, an approximation to the optimal solution can be found both graphically and math- ematically. This simple approach relates linearly the objectives with the decision variables.

The quality of the solution depends strongly on the number of solutions available to con- struct the model. Consequently, more elaborated models can be deduced if more solutions are available. This type of regression methods has different forms of being identified in the literature: design of experiments, response surface, statistical analysis, data fitting, etc.

Another kind of methodologies uses some type of information to perform the search.

In most classical algorithms, the problem is solved starting with a solution generated ran- domly in the search space and, by means of a moving rule in a unidirectional direction based on the use of local information, the algorithm progresses point-by-point to find the best solution (figure 3-A). This new optimized solution will be the starting point for the

next step, where the same procedure is repeated a number of pre-defined times. If more than one objective exists, they must be aggregated into a single objective. The differences between the available algorithms rely on the way this search direction is defined. Two types of such methods exist: direct and gradient based. In the first case, the search is only guided based on the values of the objective function and constraints, e.g., simplex search, pattern search and conjugate direction methods. These methods are usually slow, requir- ing a high number of function evaluations. The second type involves the use of infor- mation concerning the first and/or second derivative of the objective functions values and/or constraints, e.g., steepest descent and conjugate gradient methods. The use of de- rivatives hastens convergence, but these methods are unable to deal with non-differenti- able and discontinuous problems. The calculation of the derivatives must be possible, which does not often happen in real problems [17]. These methods face other difficulties:

i) the convergence is strongly dependent on the initial solution chosen, ii) the solution found is often stuck in a local sub-optimum, iii) the algorithm is unable to deal with a discrete problem and cannot take properly into account its multi-objective nature. In fact, real world optimization problems (such as polymer processing) can comprise linear and/or non-linear objective functions and constraints, discrete and/or continuous varia- bles, stochastic or deterministic inputs, and single or multiple objectives. Thus, the choice of the algorithm to use will depend strongly on the problem features [17].

Figure 3. A) Single objective optimization versus B) multi-objective optimization.

Most (if not all) real optimization problems are multiobjective, i.e., it is necessary to satisfy simultaneously several performance measures (objectives), which are often con- flicting. Also, their relative importance to the process may be subjective and can be dealt with in different ways. Mathematically, a multiobjective optimization problem can be de- fined as [18, 19]:

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x

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where M is the number of objectives.

The various objectives can be taken into account a priori, a posteriori or iteratively.

In the first case, the optimization takes place after the decision maker (DM) defines the relative importance of the objectives using, for example, weights or goals. The perfor- mance of the solutions can be obtained through the use of aggregation functions, e.g., weighted sum, weighted product, or weighted Tchebycheff metric [20]. Then, a traditional single-objective methodology can be used to find the optimum, as illustrated in figure 3- A. A weighted sum is simple, but not only it is difficult to set the weight vectors to obtain a Pareto-optimal solution in a desired region of the objective space, it does not allow to find certain Pareto-optimal solutions in a nonconvex and/or discontinuous objective space. The weighted Tchebycheff metric guarantees finding all Pareto-optimal solutions, assuming that the ideal solution in this multidimensional space (z*) is known. However, some weaknesses also exist: i) the minimum and maximum values of the objectives and of z* must be known, ii) for a small number of objectives, not all Pareto-optimal solutions are obtained, and iii) as the number of objectives increases, the problem becomes non- differentiable [18, 19]. The second alternative consists in optimizing simultaneously all the objectives without considering beforehand the preferences of the DM. The results will be a set of solutions denoted as Pareto set, were two spaces of interest exist, instead of a single one as before, i.e., the decision variables and the objectives domain, as depicted in figure 3-B. Thus, the aim of multi-objective optimization is to find feasible solutions where all objective functions are optimized. These solutions are incomparable to each other, since it is not possible to state that one is better than another in all objectives simultaneously. The Pareto solutions are the set of non-dominated solutions (the full circles in figure 3-B). In the figure, Solution 2 is better than solution 3 in both objectives, thus solution 3 is domi- nated by solution 1. The same does not happen when comparing solutions 1 and 2, as none of these solutions dominates the other. In this case, the selection of a solution can only be made using additional preference information that must be provided a posteriori by the DM [20]. Finally, the optimization and choice of solutions steps can be made itera- tively and interleaved, i.e., the optimization algorithm provides alternative solutions to the decision maker, who indicates his/her preferences, and the optimization algorithm runs again taking into account this information. The process is repeated until a satisfactory solution (or solutions) is/are found. The decision making can be performed by humans and/or by computer algorithms [21].

The better known and more widely used multi-objective optimization algorithms are based on Evolutionary Algorithms (EA). These are meta-heuristics that mimic the process of natural evolution of a population of individuals, the solutions, along successive gener- ations. They comprise Genetic Algorithms (GA), Evolutionary Programming (EP), Evolu- tion Strategies (ES) and Genetic Programming (GP). Figure 4 illustrates schematically how this type of algorithms works. The individuals with higher performance in the environ- ment will have more capacity to survive, which implies that they also have more capacity to be reproduced into the next generations. As in natural evolution, the offspring (new solutions) are generated by genetic operators such as crossover and mutation, inheriting most of the parent characteristics. The population of individuals, which are the potential solutions to the problem under study, evolves using the mechanisms of selection and var- iation. The selection operators enable the best individuals to have higher probability of being selected for generating offspring and the variation operators allow the generation of new individuals [18, 19, 22]. Selection is based on the quality of each individual, which is given by a fitness function that is associated with the objective or objective functions for single or multi-objective optimization, respectively.

Figure 4. The evolutionary cycle.

Based on the advantage of working with a population of solutions, multi-objective procedures were developed whereby the solutions evolve towards the optimal Pareto front in a single run. They are usually known as Multi-Objective Evolutionary Algorithms (MOEAs). In order to spread the population of solutions along the entire Pareto front, an additional operator measuring diversity is considered. The performance of the algorithm will depend on the balance between convergence, given by the value of the objective func- tions, and diversity, a measure of the distance between the solutions on the search space.

Convergence and diversity are combined into a single fitness operator that is responsible for the selection of the solutions to be reproduced for the subsequent generations. This can be done in three ways: i) based on Pareto dominance [22, 23], ii) scalarizing [24] and iii) using indicator algorithms [25, 26, 27]. The research on MOEAs allowed the develop- ment of other types of multi-objective algorithms, such as Ant Colony Optimization (ACO) [28], Particle Swarm Optimization (PSO) [29], Simulated Annealing (SA) [30] and Differential Evolution (DE) [31].

Another important optimization topic concerns the robustness of the solutions ob- tained, i.e., the capacity of the solutions found of being robust against, for example, changes in the design variables. This may signify that the best solutions are not the ones selected, but, instead, other solutions that perform well for different ranges of the design variables. Robustness can be taken into account through expectation measures, which quantify simultaneously fitness and robustness, or by variance measures, which assess the deviation of the original fitness in the neighborhood of the solution. Several combina- tions of expectation and variance measures have been linked to a MOEA, and applied to a few multi-objective problems, in order to select the most performing approach [32]. Gas- par-Cunha et al. [33] developed a set of benchmark problems to account for diverse types of robustness circumstances. The methodology was also assessed through application to some real problems. Figure 5 explains the concept in a multi-objective environment: solu- tion 1 is more robust than solution 2, as the same variation in the decision variables do- main produces less variation in the objectives domain.

Since the result of a MOEA is a set of solutions, the decision maker is always chal- lenged with the need to select the best (single) solution from this Pareto set. For this pur- pose, it is necessary to introduce, at some point of the optimization process, the prefer- ences of one (or more) decision maker(s). A methodology based on a weighted stress func- tion method was used for fitness assignment in MOEA [34]. This approach provides a fast convergence and a better final approximation performance, as measured by the usual quality indicators, when compared with traditional methods, such as aggregation func- tions.

Recombination Mutation

Population

Offspring Parents

Selection

Replacement

Figure 5. Concept of robustness in multi-objective environment. Solution 1 is more robust than solution 2, as the same variation in the decision variables domain (x¹,x²) produces less variation in the objectives domain (f¹,f²).

4. Optimization Algorithms in Polymer Processing

4.1. Methodology

Figure 6 displays the polymer processing sequences targeted by the present review, as they can entail optimization problems. They include single screw (A) and twin screw (B) extrusion, injection molding (C), blow molding (either based on extrusion (A3) or in- jection molding (C2)) and thermoforming (A2) (which produces 3D shapes from previ- ously extruded sheets). Typically, these processes involve a plasticating step (carried out by the plasticating unit – which is an extruder, in the case of (A) and (B)), which encom- passes material feed, melting, mixing, pressure generation and pumping, followed by shaping and cooling. All these stages can be approached as optimization problems. In the case of the plasticating unit, it may be necessary to define the screw profile, or set the operating conditions for a given polymer system/product combination. When extruding profiles (A1), the design of the extrusion die and calibrator can be approached as optimi- zation problems. Indeed, die design aims at defining the geometry of the flow channel that assures uniform melt velocity (and, if possible, also equal residence time) across the entire extrudate cross-section at the die exit. Similarly, the extrusion of flat film/sheet (A2) with uniform thickness (or a pre-defined thickness variation) along its width requires a proper design of the die. Intermeshing co-rotating twin screw extruders are extensively used in compounding and reactive extrusion operations (B), the outcome of the process consisting of a new material in pellet form, to be subsequently converted into a final prod- uct by one of the available processing techniques. Since the geometry of these machines must be adapted to the requirements of each production, which may vary significantly, the screws and barrel are often built as assemblies of individual elements (which are sup- plied with different conveying, distributive and dispersive mixing abilities). Thus, screw design consists of selecting a given number of screw elements from a larger set of possi- bilities, and position them in the right sequence. This constitutes an interesting, albeit complex, optimization problem. In injection molding (C), mold design (C1), screw design and setting the operating conditions are well recognized optimization problems. Finally, blow molding also entails optimization challenges, as discussed in section 2.

The discussion of the efforts reported in the open literature to solve the above opti- mization problems will be performed, whenever possible, using the following type of data (and respective acronyms):

1. Objective function. It can be Single Objective (SO), Aggregated Product (AP), Aggre- gated Sum (AS) or Multi-Objective (MO);

2. Optimization algorithm, e.g., Empirical, Regression, Direct, Gradient, Augmented Lagrangian (AL), Pattern Search (PS), Expert System (ES), Evolutionary Algorithm (EA), Differential Evolution (DE), Ant Colony Optimization (ACO), Stochastic Local Search (SLS), Two-Phase Local Search (TPLS);

x

x

f

f

1

2

3. Modeling approach: unidimensional (1D), two-dimensional (2D) and three-dimen- sional (3D), using Analytical (A), Finite Differences (FD), Finite Volumes (FV) or Finite Elements (FE) approaches;

4. Decision variables, i.e., parameters to optimize. The aim can be to define the Operat- ing Conditions (OC), Screw Design (SD), Screw Configuration (SC) (the last two will be explained below), Die Geometry (DG). The number of variables considered in the problem is indicated between brackets in the tables below;

5. Other characteristics, related with the process/modeling, the optimization, or others;

Figure 6. Polymer processing sequences targeted by the present review. (A) single screw extru- sion: of profiles (A1), flat film/sheet for thermoforming (A2), extrusion blow molding (A3); (B) co- rotating twin-screw compounding and pelletizing (B1); (C) injection molding: mold (C2) injection blow molding. Left: plasticizing units; Right: shaping and cooling.

4.2. Single Screw Extrusion

This section reviews the previous optimization studies of the plasticating unit of sin- gle screw extruders (SSE). The decision variables that have been considered are related with the optimization of the operating conditions (screw speed and barrel temperature profile) and/or of the screw geometry. Conventional and barrier screws, as well as units with a grooved barrel in the feed zone have been studied. Table 1 summarizes the features of the various publications found in the literature.

Table 1. Previous publications on the optimization of single screw extruders.

Objective function

Optimization Algorithm

Modelling Approach

Decision variables

Other

characteristics Authors (year) reference

SO Direct 1D-A SD Step-by-step Helmy and Parnaby (1976) [38]

SO Empirical 1D-A SD Grooves Potente et al. (1992) [39]

SO ES 1D-A OC+SD Worteberg et al. (1994) [40]

SO Empirical 1D-A SD Step-by-step Chung (1998, 2016) [8,41]

SO Empirical 1D-A SD Zone-by-zone Rauwendaal (1986) [42]

SO AL 3D-N SD Altinkaynak (2010), [43]

AP Empirical 1D-A OC Potente et al. (1993, 1994, 1996) [44,45,46]

AP Regression 1D-A SD Statistical Potente and Zelleröhr (1997) [47]

AP Regression 1D-A SD DOE Potent and Krell (1997) [48]

AP(3) Regression 1D-A OC(2)+SD(1) Wilczyński et al. (2001, 2003) [49,50]

AP(3) Regression 1D-A OC(2)+SD(1) Wilczyński et al. (2004) [51]

AS(3) Regression 1D-A SD Thibodeau and Lafleur (2000) [52,53]

AS(2) EA 1D-A OC(2)+SD(1) Nastaj and Wilczyński (2018) [54]

AS(2) EA 1D-A OC(2)+SD(1) Starve-feed Nastaj and Wilczyński (2020) [55]

AS(2) DE+PS Experimental OC(1) Various techniques Abeykoon et al. (2011, [56]

AS(4) EA 2D-N OC(4) Gaspar-Cunha et al. (1998, [57]

AS(4)+MO(4) EA 2D-N OC(4) Covas et al. (1999) [58]

MO(7) EA 2D-N SD(6) Gaspar-Cunha et al. (2001) [59]

MO(5) EA 2D-N SD(5) Barrier screws Covas et al. (2004) [60]

MO(2) EA 2D-N OC(4)+SD(6) Mixing Domingues at al. (2012) [61]

MO(5) EA 2D-N SD(4) Barrier screws Gaspar-Cunha et al. (2006) [62]

MO(19) EA 2D-N OC(3) Scale-up Covas and Gaspar-Cunha (2009) [63]

MO(9) EA 2D-N SD(4) Scale-up Gaspar-Cunha and Covas (2014) [64]

MO(3) EA 2D-N SD(4) Robustness + DM Denysiuk et al. (2018) [65]

MO(5) EA 2D-N OC(4)+SD86) Innovization Deb et al. (2014) [66]

The earliest attempts to optimize single screw extrusion used statistics, regression, and response surface analyses based on experimental data [35] and computer modelling [36, 37, 38]. Helmy and Parnaby [38] applied a steady-state hill-climbing optimization method, together with an analytical modelling routine, to design screws, this being a good example of the application of traditional optimization methods (see figure 3-A). They im- plemented an iterative procedure where the required pressure and flow rate at the die, as well as the constraints (e.g., machine dimensions, screw strength and product quality), are initially defined. The search is made considering a single objective (screw power effi- ciency). Potente et al. [39] used an 1D analytical modelling software to optimize a screw for a grooved barrel extruder, using a trial-and-error procedure. Worteberg et al. [40] em- ployed the same modelling software to develop an expert system to optimize extrusion, but recognized the required intense interaction between process simulation and expert system, in order to create a data base with an adequate dimension, capable to work with variations in operating conditions, material properties and system geometry.

Some authors claimed to design screws “scientifically”. Chung [8, 41] proposed to design the entire screw through a sequence of steps aiming to match a given output. From a balance between heat conducted and heat generated by viscous dissipation, the depths of the metering and feeding sections were defined. Then, some adjustments were made taking into account practical/empirical rules. Rauwendaal [42] defined the screw geome- try by solving the analytical equations pertaining to each functional zone in order to the relevant objectives, such as power consumption and output.

Traditional (and inefficient) methods are still being used to optimize SSE. For exam- ple, Altinkaynak [43] developed a full 3D finite element code for the melting and metering

zones, which was used to optimize the screw pitch and depth of the metering zone. How- ever, since the Augmented Lagrangian method (an algorithm for solving constrained op- timization problems) was adopted to maximize output, together with a constraint (the melt temperature at the extruder outlet could not exceed a pre-defined limit), the rele- vance of the results obtained was very limited. Hence, this work illustrates the need to find a good balance between the use of computationally demanding modelling codes and the optimization method.

Potente and co-authors [44-48] reported one of the first systematic attempts to con- sider multiple objectives by means of a simple scalar objective function, together with a 1D analytical modelling program. For instance, Potente and co-authors [44, 45, 46] as- sumed the M-square root (M is the number of objectives) of the product of the individual objectives (such as output and length of screw required for melting), to avoid any of them assuming a zero value. However, an empirical procedure was employed to optimize the process. Potente and Zelleröhr [47] optimized the process with a statistical method and a regression analysis, obtaining contour plots for the quality function from a regression analysis to the results generated by the modelling software. Potente and Krell [48] pro- posed a methodology for screw design involving a DOE (Design of Experiments) and multiple regression. A similar strategy using the STATISTICA software and a 1D analyti- cal process description was adopted by Wilczyński et al. [49, 50]. The barrel temperature, screw speed and screw channel depth in the metering zone were optimized (using a M- square root of the product of the normalized objectives) in order to maximize mass flow rate and minimize power consumption and melt temperature at the die outlet. Subse- quently [51], these results were compared with those obtained using Artificial Neural Net- works (ANN) instead of the statistical analysis. It was concluded that the statistical strat- egy produced better results. Thibodeau and Lafleur [52, 53] adopted a 5-level central com- posite statistical model to design screws that maximize mixing and minimize melt tem- perature in the feed zone through a desirability function. The optimum was found on a response surface determined by a 1D analytical modelling program.

Nastaj and Wilczyński [54] applied EAs to optimize the screw speed and the length of the metering zone that maximize output and minimize mechanical power consump- tion, with a weighted sum as global objective function. Similarly, the same authors [55]

optimized starve fed/flood fed single screw extruders in terms of screw speed, barrel tem- perature and length of the metering zone, for the same two objectives. They concluded that starve feed extrusion performs better.

Abeykoon et al. [56] compared the performance of differential evolution and particle swarm algorithms, both based on the use of a population of solutions. The aim was to find the barrel set temperatures that minimize the difference between the average melt tem- perature at the die and the temperature required by the process, as well as the temperature variance at the die. These two objectives were aggregated in a single objective function thru a weighted sum. The melt temperature was evaluated using a static nonlinear poly- nomial model whose parameters were obtained from experimental data. Data analysis allowed to build a model for evaluating the objectives, while the population based algo- rithms were used for the optimization.

Gaspar-Cunha et al. [57] analyzed the advantages and shortcomings of implementing an optimization methodology based on the interplay between a modelling package, an objective function, and an EA to solve single screw extrusion problems. The various ob- jectives were taken into account through an aggregation function (the weighted sum) to define the operating conditions (screw speed and barrel temperature profile) that pro- duced the desired output and/or product characteristics. Although the approach was able to find solutions with physical meaning, changing the weights of the aggregation function did not allow to access most of the solutions along the Pareto front, as the algorithm con- verged to the extremes of the search space. Therefore, multi-objective algorithms seem a better alternative. Indeed, upon applying a MO approach based on EAs to the same SSE problem, the trade-off between four different objectives was established, providing a bet- ter understanding of the features of the extrusion system under study [58]. Figure 7 shows

the two-dimensional Pareto fronts after optimizing the operating conditions of a SSE in order to maximize output and mixing, and minimize the length of screw required for ma- terial melting. The aim is to approach the edges, as indicated by the arrows. The best points are those near to the lines in each graph. Nevertheless, during the optimization process it was found that when more than two objectives were considered, most of the solutions were non-dominated. Thus, a new MOEA based on a clustering strategy was developed to select the solutions while maintaining the diversity along the Pareto front.

The same MOEA was used to optimize the screw geometry (described by 6 parameters) for the same SSE problem [59], the methodology being sensitive to changes in the design parameters, but obviously dependent on the ability of the modelling routine to provide precise predictions. The approach was extended to the design of Maillefer barrier screws, assuming five design screw parameters and five objectives [60]. Domingues et al. [61]

modelled the evolution of the morphology of immiscible liquid-liquid and solid-liquid systems in SSE, and used these data to compute distributive and dispersive mixing indi- ces. These were added as new objective functions to optimize the operating conditions and screw geometry using the same MOEA. Subsequently, a modified strategy was adopted to optimize all together conventional and Maillefer barrier screws [62]. A struc- tured chromosome representation was adopted, in which various parts of the chromo- some represent the same variables and the genotype representation is based on a hierar- chy (i.e., one of the decision variables is a flag indicating the type of screw). The results showed that different regions of the Pareto front are attained by the two screw types.

Figure 7. Pareto curves after optimization of the operating conditions of a SSE, in order to maxim- ize output and mixing and minimize the length of screw required for melting.

Scale-up in SSE often consists in finding the geometry and/or the operating condi- tions of a target extruder (in general, of production size) in order to obtain materials or products with the same characteristics of those developed with existing equipment (com- monly, a laboratory extruder). This should require that flow and heat transfer at the two scales are similar, but the problem is difficult to solve as changes in scale affect differently the various process parameters. Covas and Gaspar-Cunha [63] approached scale-up as a multiobjective optimization problem, where the aim is to minimize the differences in per- formance between extruders of different sizes while satisfying simultaneously several ob- jectives. Screw speed and barrel temperatures in three zones were initially assumed as

0 0.2 0.4 0.6 0.8 1

Lengthfor melting(m)

0 100 200 300 400 500

10 12 14 16 18

Output (kg/hr)

Mixing

decision variables. Subsequently, the same methodology was applied to screw design, considering four screw geometrical parameters and nine objectives [64].

Robustness and decision making strategies have also been included in the solution of SSE problems [65]. In this way, it becomes possible to focus the search on solutions that converge to regions where the preference was defined either by the relative importance of the objectives, or by considering the robustness of solutions against perturbations in the design variables. Deb et al. [66] proposed an “innovization” methodology to capture relationships between the relevant process parameters (i.e., the decision variables) and the objectives from the final results of a multi-objective optimization algorithm. After apply- ing a MOEA, the optimal trade-off solutions are analyzed and the interactions between the parameters are obtained automatically. The procedure was applied to an SSE problem, a set of rules relating the relevant decision variables with the objectives for each case stud- ied being established.

4.3. Twin-Screw Extrusion

As illustrated in Figure 8, optimization of twin-screw extruders (TSE) may involve:

i) the definition of the operating conditions (N - screw speed, Q - feed-rate and T^b - barrel temperature profile); ii) the determination of the geometry of individual screw elements;

and/or iii) the determination of the screw configuration, i.e., finding the best location along the screw axis of existing screw elements). These problems arise within the context of compounding, reactive extrusion, extrusion, or scale-up, and can involve co-rotating or counter-rotating intermeshing twin-screw extruders. Table 1 summarizes the features of the previous studies on these topics.

As with SSE, co-rotating twin-screw extruders were initially optimized using empir- ical approaches based on experimental and computational data. Potente and co-authors [67, 68] developed SIGMA, a 1D modelling software, but details on the optimization method, including design variables and objectives, were not given. The results achieved seem to have been based on a trial-and-error procedure. Vainio et al. [69] investigated ex- perimentally different screw profiles for the preparation of an uncompatibilized immisci- ble PA6/PP blend, with the aim of optimizing the screw configuration. Although the pro- cess parameters influencing mixing were identified, no systematic optimization method was offered. Berzin et al. [70] optimized graphically the cationization of wheat starch in a laboratory extruder in terms of screw configuration and operating conditions, taking into account geometrical and process constraints, with the aim of scaling-up the results to a larger industrial extruder. Five different screw configurations were analyzed, assuming the minimization of the specific mechanical energy and the maximization of the reaction efficiency. The scale-up procedure used the same type of data for screws geometrically similar to those studied for the smaller extruder.

Figure 8. Optimization of co-rotating twin-screw extruders (TSE): i) operating conditions, screw speed (N), feed rate (Q) and barrel and die set temperatures (Tb); ii) geometry of individual screw elements; iii) position of a set of individual screw elements (5 conveying elements, 3 kneading blocks and 1 left handed element) along the screw shaft.

Table 2. Previous publications on the optimization of twin-screw extruders.

Objective function

Optimization Algorithm

Modelling Approach

Decision variables

Other

characteristics Authors (year) reference Not defined Empirical 1D-A Not defined Potente et al. (1994, 1999) [67,68]

SO Empirical Experimental Not-defined Mixing Vainio et al. (1995) [69]

SO(2) Regression 1D-Ludovic OC(3)+SD(1) Reactive Extrusion Berzin et al. (2007) [70]

SO Regression Experimental OC(2) Counter-rotating Maridass and Gupta (2004, [71]

SO(2) Regression Experimental OC Reactive Extrusion Ulitzsh et al. (2020) [72]

SO(2) Regression Experimental OC(2) Scale-up Fukuda et al. (2015) [73]

AP(3) Gradient 1D-A SD(2) Conv. elements Potente and Thümen(2006) [74]

AS(2) EA 2D-numerical OC(1)+SD(1) Reactive Extrusion Zhang et al. (2015) [75]

AS+MO(6) EA 1D-Ludovic OC(4) Gaspar-Cunha et al. (2002) [76]

MO(7+2) EA 1D-Ludovic OC(4)+SC(10) Reactive Extrusion Gaspar-Cunha et al. (2005) [78]

MO(5)(7) EA 1D-Ludovic SD(4)+SC(10) Robustness Covas et al. (2004) [60]

MO(3) SLS 2D-FD SC(14) Teixeira et al. (2011) [80]

MO(3) EA+ACO+SLS+TPLS 2D-FD SC(14) Teixeira et al. (2012) [81]

MO(3) ACO+TPLS 2D-FD SC(14) Teixeira et al. (2014) [82]

MO(3) EA 1D-Ludovic OC(1)+SC(14) Reactive Extrusion Teixeira et al. (2011) [83]

MO(3) EA 2D-FD SD(1)+SC(8) Scale-up Covas et al. (2011) [84]

Various authors adopted statistical methods for TSE optimization. The analysis ap- plied by Maridass and Gupta [71] was based on experimental data on the recycling of natural rubber vulcanizates in a counter rotating twin screw extruder. The aim was to find

the barrel temperature and screw speed that maximized the properties of the material obtained. For that purpose, the contour plots obtained were analyzed visually. Ulitzsch et al. [72] selected a response surface methodology to optimize the synthesis of vinyltri- methoxysilane-grafted ethylene-octene-copolymer using experimental data. Five process parameters and their interactions were optimized, in order to maximize both the grafting degree and efficiency. Second-order interaction effects existed, making this process diffi- cult to control with such a simple optimization methodology. Fukuda et al. [73] used a DOE to analyzed separately two different scale-up rules, one based on the volumetric flow rate, the other related to dispersive mixing, with the aim of optimizing the operating con- ditions of the target extruder.

Potente and Thümen [74] applied a gradient method to optimize the radial and flight clearances of conveying screw elements, in order to maximize the pressure gradient and minimize the temperature gradient and power consumption.

Zhang et al. [75] employed a single objective EA to optimize free radical bulk polymerization, with the aim of defining the barrel temperature and screw length that maximize both monomer conversion and monomer conversion per unit energy consump- tion. A weighted sum took into account the two objectives. A weighted sum and a MOEA were adopted to set the operating conditions of three extruders with different screw con- figurations [76], while using the Ludovic software [77] to evaluate the objective functions.

When optimizing operating conditions, or the geometry of individual screw ele- ments, the characteristics of these tasks are identical to those of equivalent SSE problems, since the decision variables to optimize vary continuously in the search space. However, defining the best location of screw elements along the screw shaft is a discrete and com- binatory problem. Gaspar-Cunha et al. [78] used a modified MOEA to define the most adequate location of a pre-selected set of screw elements (denoted as screw configuration problem, SC). An analogy was made with the traveling salesman problem, or sequencing problem in operations research, with the cities being the screw elements that must be cov- ered sequentially by the traveling salesman in order to maximize a prescribed perfor- mance. Within the obvious limitations of the exercise, the results were validated experi- mentally and the methodology was also applied to -caprolactam polymerization via re- active extrusion. Later, the robustness of the solutions, considering changes in the value of the decision variables, was also taken into account [60]. An alternative approach using Stochastic Local Search (SLS) algorithms to tackle the SC problem was also attempted [79].

An efficient single-objective iterative improvement strategy, based on various neighbor- hood structures, neighborhood search strategies, and neighborhood restrictions, was pro- posed, whereby the algorithms were embedded into a variation of a bi-objective two- phase local search (TPLS) framework. The results were compared to those obtained by the previous MOEA, evidencing a higher quality approximation to the Pareto front, with a faster convergence. Process modelling contained of a global plasticating treatment co-ro- tating twin screw extrusion [80]. Given the good results obtained, Teixeira et al. [81] solved the SC problem through the hybridization of different local search procedures, including Pareto local search and TPLS algorithms, with two different population-based algorithms, a MOEA and a Multi-Objective Ant Colony (MOACO). This approach outperformed the other algorithms studied and their combinations. With the aim of exploring the full po- tential of the hybrid algorithm, the influence of the MOACO algorithm parameters was investigated, and the results obtained were compared with those of MOEA and TPLS al- gorithms [82]. It was concluded that the hybridization of the MOACO algorithm has a significant potential for solving the SC problem.

Teixeira et al. [83] adopted a MOEA algorithm to solve the SC problem for starch cationization by reactive extrusion, aiming at the minimization of the specific mechanical energy and the maximization of output and reaction conversion. As far as scale-up in TSE is concerned, Gaspar-Cunha and Covas [84] employed a multi-objective optimization strategy to define the geometry (location of eight screw elements) and operating condi- tions of the target extruder that minimized the differences in viscous dissipation, specific mechanical energy and average strain between the target and reference machines.

4.4. Dies and Calibrators

Extrusion dies aim at converting the circular flow at the outlet of the extruder into a flow with a specific cross-section (to produce film/sheet, pipes, profiles, etc). The latter may not correspond to the actual product cross-section/dimensions, as the die geometry must compensate for all the shape/dimensional changes of the extrudate along the extru- sion line. As a matter of fact, due to its viscoelastic nature, the extrudate will swell pro- gressively as it leaves the die, but this might be partially/totally offset by the draw down created by the haul-off. During cooling, thickness differences may arise in the cross-sec- tion due to gravity flow, and the extrudate will shrink and might distort due to buoyancy forces in a water tank. Thus, not only extrusion dies are built in such a way that they attempt to anticipate subsequent changes in the shape of the extrudate, they allow for some local adjustments in the channel geometry. Also, whenever possible, the external contour of the extrudate is corrected prior to cooling by means of a calibrator.

Extrusion dies usually comprise an adapter, which converts the circular flow from the extruder into the required channel shape for extrusion, and a parallel zone with con- stant cross-section, which allows for some macromolecular relaxation. The ensemble adapter/parallel zone should be designed in such a way that the velocity and the residence time of all the individual melt streams in the cross-section are uniform. To ensure this, and despite of the wide variety of extruded shapes, there are generally three approaches to design the adapter:

i) using a manifold, i.e., use a larger channel upstream to distribute the flow transver- sally, prior to its progress downstream. The die geometry is such that a central flow stream has a shorter path in the manifold and a longer path in the shallower parallel zone, while the reverse occurs for a flow stream near to the edges. This approach is frequently adopted for the production of cast film and sheet, wire insulation and extrusion blow molding.

ii) using a cylindrical mandrel to convert the circular flow from the extruder into an annular flow. Since the classical torpedo-type solution with its supports (known as spider legs) creates unbalanced flow and strong welding lines, it was progressively replaced by basket-type dies and spiral mandrel dies. The mandrels of the latter are designed in such a way that the flow from the extruder is divided into individual melts which feed helical channels with decreasing depth along their length in the mandrel. Thus, the helical flow is gradually converted into an axial annular flow.

iii) using an adapter to change gradually from the inlet circular channel into the desired cross-section. The design of dies for hollow profiles, or for profiles containing thick- ness differences in their cross-section is particularly challenging.

Rakos and Sebastian [85] proposed an empirical optimization procedure to define the geometry of different types of dies using a numerical modelling code, but no details were given concerning the objectives and design variables. In the following sections, each type of die is studied separately

4.4.1. Manifold Dies

Matsubara [86, 87] solved the analytical flow modelling equations in order to a major design variable (the variation along the length of the manifold radius) of a coat hanger die that assured uniform flow rate and residence time across the width, and extended the methodology to T-dies [88, 89]. Table 3 shows that the design of manifold dies as an opti- mization problem was carried out using a single objective function, and that as optimiza- tion procedure empirical methods, regression analyses, sequential quadratic programing, gradient techniques, or evolutionary algorithms were adopted.

Table 3. Previous publications on the optimization of manifold dies (manifold type: CH- Coat Hanger, TCH- Tapered Coat Hanger, Blow – blow molding)

Objective function

Optimization Algorithm

Modelling Approach

Decision variables

Other

characteristics Authors (year) reference Not defined Empirical 1D-A DG(?) Various dies Rakos and Sebastian (1990) [85]

SO Empirical 1D-A DG(1) CH Matsubara (1979, 1980) [86,87]

SO Empirical 1D-A DG(1) T-die Matsubara (1980, 1988) [88,89]

SO Empirical 1D-A DG(3) CH Winter and Fritz (1986) [90]

SO Empirical 3D-N DG(3) CH Liu et al. (1988, 1994) [91]

SO Empirical 3D-N DG(4) TCH, 2 cavities Lee and Liu (1989) [92]

SO Empirical 3D-N DG(3) CH Liu et al. (1988, 1994) [93]

SO Empirical 3D-N DG(4) TCH Yu and Liu (1998) [94]

SO Empirical 3D-N DG(3) CH Na and Kim (1995) [95]

SO Empirical 2D-N DG(2) CH Huang et al. (2004) [96]

SO Regression 1D-A OC(1)+DG(3) CH Chen et al. (1997) [97]

SO Regression 3D-N DG(5) CH Razeghiyadaki et al. (2020, 2021) [98,99]

SO SQP + Regression 3D-N DG(1) CH Lebaal et al. (2006) [100]

SO SQP + Regression 3D-N DG(4) CH Lebaal et al. (2009) [101]

SO SQP + Regression 3D-N OC(3)+DG(1) CH Lebaal et al. (2010) [102]

SO SQP + Regression 3D-N DG(4) CH (wire) Lebaal et al. (2012) [103]

SO Gradient 3D-N DG(2) CH Smith et al. (1998, 1998) [104,105]

SO Gradient 3D-N OC(1)+DG(2) CH Smith (2003) [106]

SO Gradient 3D-N DG(811) CH, Robustness Smith (2003) [107]

SO Gradient 3D-N DG(9) CH Sun and Gupta (2004) [108]

SO Gradient 3D-N DG(5) CH, Restrictor Bates et al. (2003) [109]

SO Regression+

Gradient+EA 3D-N DG(5) CH, Restrictor Siens et al. (2006) [110]

SO EA 3D-N DG(n) CH Michaeli and Kaul (2004) [11]

SO EA 3D-N DG(2) CH Meng and Zhao (2011) [112]

SO EA 3D-N DG(4) Slot die Sun and Wang (2010) [113]

SO EA 3D-N DG(2) Blow: 2-CH Meng et al. (2009, 2012) [114,115]

AS(2) Regression 3D-N DG(3) CH Han and Wang (2012) [116]

AS(n) Gradient 3D-N OC(1)+DG(2) CH, Robustness Smith and Wang (2004) [117]

AS(n) Gradient 3D-N OC(1)+DG(2) CH Smith and Wang (2005) [118]

AS(n) SQP 3D-N OC(1)+DG(2) CH Wang and Smith (2006) [119,120]

AS(3) EA 3D-N OC()+DG() CH Zhang et al. (2020) [121]

MO(2) DOE, RSM, EA 3D-N DG(3/8/12) CH Lee et al. (2015) [122]

MO(2) EA 3D-N DG(3) CH Han and Wang (2012) [123]

AS(2) &

MO(2) Regression + EA 3D-N DG(1) Blow: 2-CH Han and Wang (2014) [124]

Winter and Fritz [90] recommended the use of a specific design procedure for a coat hanger die, taking into account uniformity of the exit velocity and average residence time, regardless of flow rate or polymer viscosity, and considering separation of the flows. The geometry of dies with a square and circular manifold and constant thickness of the parallel section was defined, in which the design variables were the width or the diameter of the manifold, as a function of its length, and the height of the parallel section.

Liu et al. [91] developed a method to optimize coat hanger dies with non-circular manifold, to avoid dead spots in the transition to the parallel zone. The aim was to define the geometries of the manifold and parallel zone in order to deliver uniform flow, while

keeping uniform residential time distribution for different polymers and operating con- ditions. A numerical modelling program was used to evaluate the solutions. The same empirical strategy was used by Lee and Liu [92] to design a coat-hanger die with a line- arly-tapered inner cavity and a straight outer cavity, but taking into account inertial, grav- itational, and viscous effects. Later, Liu et al [93] and Yu and Liu [94] proposed a unified lubrication approximation to model the polymer flow inside the die with the aim of de- signing the same coat-hanger die [93] and a tapered coat-hanger die [94].

Na and Kim[95] applied an empirical approach to design linearly tapered coat- hanger dies with circular manifold (in terms of slot thickness, manifold angle and land length) with the aim of obtaining uniform flow rate distribution at the die exit in the trans- verse direction, using a 3D finite element modelling code. Even recently, a simple empir- ical approach was used by Huang et al. [96] to design coat hanger dies that maximize the uniformity of the velocity distribution at the die exit defining as decision variables the manifold radius and angle and slit height.

The application of regression techniques, based, for example, in Taguchi methods, enabled the development of more systematic optimization approaches. This is the case of Chen et al. [97], who investigated the effect of material rheology, gap thickness, manifold angle, and flow rate, on the thickness uniformity of coat hanger dies. The Taguchi method was used to optimize the geometry of dies with different widths, the solutions being eval- uated with an analytical model, and flow rate was also appended as design variable. Re- cently, Razeghiyadaki et al. [98, 99] used a response surface method to optimize the geom- etry of a coat hanger die in order to obtain uniform velocity at the die lips. The response surface was generated from computations using a commercial package, and a central com- posite DOE defined the conditions for the calculations. A spline curve was used to outline the geometry using five variables (depth and the width of the die and three nodes of the spline). The optimization involved minimizing the quadratic function obtained. Lebaal et al. [100] determined the geometry of a coat-hanger die using a global response surface method with Kriging interpolation (a regression technique), and Sequential Quadratic Programming (SQP) to minimize the global difference between the local velocities at the die exit and the average value, assuming as decision variable the depth of the distribution channel, and as restriction the pressure required by the flow. Later, four decision variables were considered, namely the depth and the opening of the channel repartition, the gap, and the height of the relaxation zone [101]. The same methodology was applied to define the depth of the distribution channel and the operating conditions [102], as well as to de- sign a wire coat hanger based on the same flow balance principle [103]. It is important to note that SQP requires that the objective function and the constraints are twice differenti- able, which was possible in this case because the objective function and the constraints were defined by regression prior to the application of SQP.

Smith et al. [104] proposed a systematic optimization methodology combining pro- cess modeling, a design sensitivity analysis (using both direct and adjoint methods), and optimization based on a gradient technique. The aim was to keep the non-uniformity of the velocity profile across the die exit below a certain level, and to minimize pressure drop, i.e., to achieve product homogeneity with minimal processing cost. The design var- iables were the length of the parallel zone and the cross section of the flow channel. The residence time in the die was considered subsequently [105]. Then, with the aim of mini- mizing the die length and to satisfy constraints related to uniform residence time and exit velocity, the inlet pressure, the manifold height and the shape of the parallel zone were taken as variables [106]. Also, to determine the geometry of a sheet die that will best ac- commodate a range of operating conditions, Smith [107] optimized 811 half-height design variables that describe the die cavity thickness distribution for an example where the inlet and outlet die half-heights are fixed. Sun and Gupta [108] applied a gradient quadratic penalty method to define the geometry of a coat hanger die (using nine decision variables), that minimizes the velocity variation across the die exit without excessively increasing the pressure drop. The penalty method consisted in adding a burden to the objective function for surpassing a pressure drop threshold. Bates et al. [109] applied a gradient optimization

method to determine the optimum geometrical profiles of a restrictor (choker bar) neces- sary to obtain a uniform flow distribution of a slit die to be used in a range of applications involving three materials with varying degrees of shear thinning, each at a high and a low flow rate. The restrictor was optimized considering the height of five points along half the width of the die. Later, this study was extended to include regression and EA optimization algorithms [110].

A single objective EA was used by Michaeli and Kaul [111] to optimize a T-shaped manifold, in order to minimize the standard deviation of the local velocities at the die exit, the decision variables being a few points in the mesh that defined the flow path. The same optimization strategy was applied to define the geometry of a coat hanger die taking as design variables two parameters related with the radius of the manifold and the height of the parallel zone [112]. Also using a single objective EA, Sun and Wang [113] optimized four geometrical parameters of the manifold. The aim was to minimize the stagnation temperature (a combination of static and kinetic temperatures), and the solutions were evaluated using a 3D numerical commercial modeling code. Meng et al. [114, 115] de- signed a double coat hanger die with a manifold of quadratic geometry in order to dis- tribute uniformly the melt across a large width. A single objective EA was selected to de- fine the gap and the manifold angle.

Several authors recognized the need to take in several objectives, hence using aggre- gation functions (e.g., weighted sum) together with single objective optimization algo- rithms. Han and Wang [116] applied a regression technique (based on an orthogonal array design) to determine the manifold angle and gap height of a coat-hanger die that minimize the variation of the outlet velocity and the residence time, using a 3D numerical modeling code. The same optimization methodology (see also [104]) was used to include the effect of the variability of the set temperature or of material properties, i.e., a robustness analysis.

In this case, the objective function was the weight sum of the inlet pressures for each flow condition that are induced by changes in temperature and/or material properties [117, 118]. An arbitrary gap height distribution in the manifold and different polymer rheolog- ical models were also added [118]. Wang and Smith [119, 120] solved the same problem using SQP. Zhang et al. [121] optimized the geometry and operating conditions of a coat hanger die using a single objective EA consisting of the weighted sum of three objectives (minimization of the mechanical deformation of the die, of the pressure drop and of the variation of the outlet velocity). The solutions to be evaluated were obtained through the application of a DOE, from which a regression model was obtained to be used by the EA.

Only recently MO optimization methods have been applied to the definition of the die geometry. Lee et al. [122] evaluated the performance of different optimization strate- gies (comprising a design of experiments, the response surface model and two different MOEAs) for the delineation of the geometry of a coat hanger die. The latter was divided in sectors that resulted in three case studies involving the definition of three, eight and twelve design variables, respectively. In parallel, two objectives were selected, minimiza- tion of the total pressure drop and maximization of a flow uniformity parameter, which were evaluated using a commercial 3D modeling software. Considering simultaneously these two objectives, Han and Wang [123] used a MOEA to optimize the same geometrical parameters, taking as starting point the geometry of a previously optimized die [116].

Later, the same authors [124] optimized a double coat-hanger die with a quadratic geom- etry manifold using identical optimization techniques (regression and MOEA).

4.4.3. Mandrel Dies

Table 4 identifies the previous studies concerning the optimization of mandrel dies.

Huang [125] proposed a strategy with two steps to optimize the geometry of a spiral man- drel die (that can be utilized for the extrusion of pipes and blown films). The Taguchi method was used to define a set of geometries able to assess the flow balance principle, then this set of geometries were evaluated iteratively taking into account total pressure drop, degree of mixing and residence time distribution. It was concluded that the best solution to use in real practice results from a balance between the different objectives,